A deep first-order system least squares method for the obstacle problem
Numerical Analysis
2025-08-28 v1 Numerical Analysis
Abstract
We propose a deep learning approach to the obstacle problem inspired by the first-order system least-squares (FOSLS) framework. This method reformulates the problem as a convex minimization task; by simultaneously approximating the solution, gradient, and Lagrange multiplier, our approach provides a flexible, mesh-free alternative that scales efficiently to high-dimensional settings. Key theoretical contributions include the coercivity and local Lipschitz continuity of the proposed least-squares functional, along with convergence guarantees via -convergence theory under mild regularity assumptions. Numerical experiments in dimensions up to 20 demonstrate the method's robustness and scalability, even on non-Lipschitz domains.
Cite
@article{arxiv.2508.19412,
title = {A deep first-order system least squares method for the obstacle problem},
author = {Gabriel Acosta and Eugenia Belén and Francisco M. Bersetche and Juan Pablo Borthagaray},
journal= {arXiv preprint arXiv:2508.19412},
year = {2025}
}